Characterization of leukocyte enzymes involved in the release of amino acids in incubated blood cell lysates

The neutral leukocyte proteases involved in the release of free amino acids in incubation mixtures of blood cell lysates and of human serum albumin with leukocyte lysates were characterized by several techniques including 1H nuclear magnetic resonance spectroscopy, electrophoresis, high performance liquid chromatography, gel filtration, amino acid analysis, and NH2-terminal analysis. The data suggested that the enzymes which contributed significantly to the extensive protein hydrolysis observed were two endopeptidases and three exopeptidases. Identification and analysis of the products obtained in incubation mixtures of human serum albumin with elastase and leucine aminopeptidase were compared with the products obtained in incubation mixtures of the protein with leukocyte lysates.     

Individual assignments of the methyl resonances in the 1H nuclear magnetic resonance spectrum of the basic pancreatic trypsin inhibitor.

In earlier work the resonances of the 20 methyl groups in the basic pancreatic trypsin inhibitor (BPTI) had been identified in the 360-MHz 1H nuclear magnetic resonance (NMR) spectra and most of the methyl lines had from spin-decoupling experiments been assigned to the different types of amino acid residues. The assignments to the different amino acid types were now completed by studies of the saturation transfer between the denatured and the globular forms of the inhibitor and by spin-decoupling experiments in nuclear Overhauser enhancement (NOE) difference spectra. These distinguished between the methyl resonances of Ala and Thr. Furthermore, for most of the methyl resonances, individual assignments to specific residues in the amino acid sequence were obtained from measurements of intramolecular proton-proton NOE's, use of lanthanide NMR shift and relaxation probes, and comparative studies of various chemically modified forms of BPTI. These data provide the basis for individual assignments of the methyl 13C NMR lines in BPTI and for detailed investigations of the relations between the spatial structure of the protein and the chemical shifts of the methyl groups. The methyl groups in BPTI are of particular interest since they are located almost exclusively on the surface of the protein and thus represent potential natural NMR probes for studies of the protein-protein interactions in the complexes formed between BPTI and a variety of proteases.     

Solution structure of mitochondrial cytochrome c. II. 1H nuclear magnetic resonance of ferrocytochrome c

The 1H nuclear magnetic resonance spectrum of tuna ferrocytochrome c has been studied and the resonances of all 49 amino acid methyl groups have been assigned to specific absorption lines. In comparison with resonance assignments in the ferricytochrome c spectrum, the secondary shifts of resonances of ferrocytochrome c are smaller and the identification of characteristic spin-systems from comparison of spectra from homologous proteins more difficult. For this reason, two-dimensional nuclear magnetic resonance exchange correlated spectroscopy has been used to correlate the assigned resonances of tuna ferricytochrome c with previously unassigned resonances of tuna ferrocytochrome c.     

Solution structure of mitochondrial cytochrome c. I. 1H nuclear magnetic resonance of ferricytochrome c

The 1H nuclear magnetic resonance spectra of tuna and horse ferricytochromes c have been investigated and the resonances of all amino acid methyl groups have been assigned to specific absorption lines. The assignment procedure involves principally the comparison of one-dimensional nuclear magnetic resonance spectra from a range of homologous ferricytochromes c and does not require a prior knowledge of the secondary or tertiary protein structure. Of the 49 methyl groups of tuna cytochrome c, the assignment of 33 is made without reference to the X-ray crystal structure. The method should therefore be applicable to other proteins of similar size where X-ray structures are unavailable. The assignments will be used to investigate the structure of cytochrome c in solution.     

Assignment of acyl chain resonances from membranes of mammalian cells by two-dimensional NMR methods

Two-dimensional nuclear magnetic resonance (NMR) methods have been successfully used to assign resonances in the 1H NMR spectrum of intact viable rat mammary adenocarcinoma cells. Two-dimensional scalar-correlated spectroscopy identifies connectivities for resonances of the lipid acyl chains in the plasma membrane of these cells. We expect that two-dimensional scalar-correlated methods may be of general use for providing unequivocal assignments in the complex and often poorly resolved 1H NMR spectra of cells.     

Proton nuclear magnetic resonance studies of intact native bovine parathyroid hormone

Native intact bovine PTH was studied by proton nuclear magnetic resonance (NMR) techniques, at pH 3.5 and pH 6.3. The 1H-NMR spectra had good resolution and many multiplet structures were observed. Assignment of the NMR resonances corresponding to specific amino acids was approached using 1H chemical shifts, coupling constants, and pH dependence in the one-dimensional spectra and the 1H-1H connectivities revealed in two-dimensional homonuclear correlated spectroscopy (COSY) experiments. All the aromatic proton resonances were assigned. Two histidine residues had lower pK than the other two. The methyl groups of two residues were moved significantly downfield: using COSY and two-dimensional nuclear Overhauser enhancement spectroscopy (NOESY) correlations, these were assigned to an alanine residue close to both Trp-23 and Tyr-43, and a valine residue in close spatial proximity to Trp-23. The NOESY spectrum also showed cross-peaks between the residues of the upfield valine-leucine-isoleucine methyl envelope. Many of the H alpha protons moved upfield as the pH was increased. These results indicate that intact native PTH exists in a preferred conformation in solution at pH 6.5. Our studies have provided new information on the three-dimensional spatial proximity of several amino acids along the polypeptide chain. The observed interactions are consistent with the currently accepted model suggesting that the hormone has two separate structural domains associated with the amino- and carboxy-terminal regions of the molecule respectively. The potential implications of this model for the expression of biological activity are discussed.     

1H NMR visible lipids in the life and death of cells

A functionally and metabolically interesting class of cell lipid can be observed by 1H nuclear magnetic resonance (NMR) spectroscopy in situ. These prominent resonances are not only associated with malignancy and cell death, but also act as heralds of benign processes, such as cell activation and proliferation. Originally, these NMR observations were explained with a membrane lipid microdomain model. However, recent studies have identified intracellular droplets, so called lipid bodies, as important contributors to these resonances. This finding bears novel implications for our understanding and assessment of lipid biochemistry in the life and death of cells.     

1H Nmr studies at 360 MHz of the methyl groups in native and chemically modified basic pancreatic trypsin inhibitor (BPTI).

In the 1H NMR spectra obtained at 360 MHz after digital resolution enhancement, the multiplet resonances of the methyl groups in the basic pancreatic trypsin inhibitor (BPTI) were resolved. With suitable double irradiation techniques the individual methyl resonances were assigned to the different types of aliphatic amino acid residues. Furthermore, from pH titration and comparison of the native protein with chemically modified BPTI, the resonance lines of Ala 16 in the active site and Ala 58 at the C-terminus were identified. Potential applications of the resolved methyl resonances as natural NMR probes for studies of the molecular conformation are discussed.     

1H NMR spectroscopy of Paracoccus denitrificans cytochrome c-550

The 1H NMR spectra of ferri- and ferro-cytochrome c-550 from Paracoccus denitrificans (ATCC 13543) have been investigated at 300 MHz. The ferri-cytochrome c-550 shows hyperfine-shifted heme methyl resonances at 29.90, 29.10, 16.70, and 12.95 ppm and a ligand methionyl methyl resonance at -15.80 ppm (pH 8 and 23 degrees C). Four pH-linked structural transitions were detected in spectra taken as a function of pH. The transitions have been interpreted as loss of the histidine heme ligand (pK less than or equal to 3), ionization of a buried heme propionate (pK = 6.3 +/- 0.2), displacement of the methionine heme ligand by a lysyl amino group (pK congruent to 10.5), and loss of the lysyl ligand (pK greater than or equal to 11.3). The temperature behavior of hyperfine-shifted resonances was determined. Two heme methyl resonances (at 16.70 and 12.95 ppm) showed downfield hyperfine shifts with increasing temperature. The cyanoferricytochrome had methyl resonances at 23.3, 20.1, and 19.4 ppm. NMR spectroscopy did not detect the formation of a complex with azide. The second-order rate constant for electron transfer between ferric and ferrous forms was determined to be 1.6 X 10(4) M-1 s-1. Heme proton resonances were assigned in both oxidation states by cross-saturation and nuclear Overhauser enhancement experiments. Spin-coupling patterns in the aromatic region of the ferro-cytochrome spectrum were investigated.     

Dynamic assessment of hexose monophosphate shunt activity in the intact rabbit lens by proton NMR spectroscopy

A proton nuclear magnetic resonance technique is demonstrated for ascertaining the real-time contribution of the hexose monophosphate shunt to glucose metabolism in the intact incubated rabbit lens. This measurement requires incubation of the tissue in medium supplemented with [1-13C]glucose, and depends on the presence of the 13C label in the methyl position of lactate which creates satellite resonances by way of 13C - 1H spin-spin scalar coupling. The assumptions required to make the measurement are presented. For lenses maintained under control conditions, a basal level corresponding to 5% hexose monophosphate shunt activity was determined. An eight-fold increase in activity was observed under conditions known to stimulate the shunt.     

1H NMR studies at 360 Mhz of the methyl groups in native and chemically modified basic pancreatic trypsin inhibitor (BPTI)

In the ¹H NMR spectra obtained at 360 MHz after digital resolution enhancement, the multiplet resonances of the methyl groups in the basic pancreatic trypsin inhibitor (BPTI) were resolved. With suitable double irradiation techniques the individual methyl resonances were assigned to the different types of aliphatic amino acid residues. Furthermore, from pH titration and comparison of the native protein with chemically modified BPTI, the resonance lines of Ala 16 in the active site and Ala 58 at the C-terminus were identified. Potential applications of the resolved methyl resonances as natural NMR probes for studies of the molecular conformations are discussed.     

A proton nuclear magnetic resonance study on the solution structure of crotamine

Proton nuclear magnetic resonance (NMR) spectra of crotamine, a myotoxic protein from a Brazilian rattlesnake (Crotalus durissus terrificus), have been analyzed. All the aromatic proton resonances have been assigned to amino acid types, and those from Tyr-1, Phe-12, and Phe-25 to the individual residues. ThepH dependence of the chemical shifts of the aromatic proton resonances indicates that Tyr-1 and one of the two histidines (His-5 or His-10) are in close proximity. A conformational transition takes place at acidicpH, together with immobilization of Met-28 and His-5 or His-10. Two sets of proton resonances have been observed for He-17 and His-5 or His-10, which suggests the presence of two structural states for the crotamine molecule in solution.     

Qualitative aspects of hydrogen-deuterium exchange in the 1H, 13C, and 15N nuclear magnetic resonance spectra of viomycin in aqueous solution.

The 1H, 13C, and 15N high field nuclear magnetic resonance spectra of the cyclic peptide viomycin have been fully assigned using homo- and heteronuclear double resonance experiments and pH effects. In addition it is shown how the two- and three-bond H-D isotope effects upon carbonyl resonances may assist in their assignment. The resistance to exchange with solvent water of the amide proton involved in the transannular hydrogen bond is observed directly in the 1H spectra, via the isotope effect on a carbonyl resonance in the 13C spectra, and via the one-bond 1H couppling in the 15N spectra.     

Nuclear-magnetic-resonance studies of eukaryotic cytochrome c. Assignment of resonances of aliphatic amino acids

The aliphatic regions of the nuclear magnetic resonance spectra of horse ferricytochrome c and horse ferrocytochrome c are described. Resonance assignments have been made using NMR double-resonance techniques, spectral comparison of related proteins, the perturbing effects of extrinsic probes, and from knowledge of the X-ray structure of cytochrome c. There are eight firmly assigned methyl resonances of ferrocytochrome c and seven firmly assigned methyl resonances of ferricytochrome c.     

Proton and carbon-13 nuclear magnetic resonance studies of rhodopsin-phospholipid interactions

Proton and carbon-13 nuclear magnetic resonance (1H and 13C NMR) spectra of rhodopsin-phospholipid membrane vesicles and sonicated disk membranes are presented and discussed. The presence of rhodopsin in egg phosphatidylcholine vesicles results in homogeneous broadening of the methylene and methyl resonances. This effect is enhanced with increasing rhodopsin content and decreased by increasing temperature. The proton NMR data indicate the phospholipid molecules exchange rapidly (less than 10(-3) s) between the bulk membrane lipid and the lipid in the immediate proximity of the rhodopsin. These interactions result in a reduction in either or both the frequency and amplitude of the tilting motion of the acyl chains. The 13C NMR spectra identify the acyl chains and the glycerol backbone as the major sites of protein lipid interaction. In the disk membranes the saturated sn-1 acyl chain is significantly more strongly immobilized than the polyunsaturated sn-2 acyl chain. This suggest a membrane model in which the lipid molecules preferentially solvate the protein with the sn-1 chain, which we term an edge-on orientation. The NMR data on rhodopsin-asolectin membrane vesicles demonstrate that the lipid composition is not altered during reconstitution of the membranes from purified rhodopsin and lipids in detergent.     

A proton nuclear magnetic resonance investigation of histine-binding protein J of salmonella typhimurium: A model for transport of L-histidine across cytoplasmic membrane

Genetic evidence suggests that the high-affinity L-histidine transport in Salmonella typhimurium requires the participation of a periplasmic binding protein (histidine-binding protein J) and two other proteins (P and Q proteins). The histidine-binding protein J binds L-histidine as the first step in the high-affinity active transport of this amino acid across the cytoplasmic membrane. High-resolution proton nuclear magnetic resonance spectroscopy at 600 MHz is used to investigate the conformations of this protein in the absence and presence of substrate. Previous nuclear magnetic resonance results reported by this laboratory have shown that there are extensive spectral changes in this protein upon the addition of L-histidine. When resonances from individual amino acid residues of a protein can be resolved in the proton nuclear magnetic resonance spectrum, a great deal of detailed information about substrate-induced structural changes can be obtained. In order to gain a deeper insight into the nature of these structural changes, deuterated phenylalanine or tyrosine has been incorporated into the bacteria. Proton nuclear magnetic resonance spectra of selectively deuterated histidine-binding protein J were obtained and compared to the normal protein. Several of the proton resonances have been assigned to the various aromatic amino acid residues of this protein. A model for the high-affinity transport of L-histidine across the cytoplasmic membrane of S typhimurium is proposed. This model, which is a version of the pore model, assumes that both P and Q proteins are membrane-bound and that the interface between these two proteins forms the channel for the passage of substrate. The histidine-binding protein J serves as the “key” for the opening of the channel for the passage of L-histidine. In the absence of substrate, this channel or gate is closed owing to a lack of appropriate interactions among these three proteins. The channel can be opened upon receiving a specific signal from the “key”; namely, the substrate-induced conformational changes in the histidine-binding protein J molecule. This model is consistent with available experimental evidence for the high-affinity transport of L-histidine across the cytoplasmic membrane of S typhimurium.     

1H-NMR comparative study of the active site in shark (Galeorhinus japonicus), horse, and sperm whale deoxy myoglobins.

1H-NMR spectra of deoxy myoglobins (Mbs) from shark (Galeorhinus japonicus), horse, and sperm whale have been studied to gain insights into their active site structure. It has been demonstrated for the first time that nuclear Overhauser effect (NOE) can be observed between heme peripheral side-chain proton resonances of these paramagnetic complexes. Val-E11 methyl and His-F8 C delta H proton resonances of these Mbs were also assigned from the characteristic shift and line width. The hyperfine shift of the former resonance was used to calculate the magnetic anisotropy of the protein. The shift analysis of the latter resonance, together with the previously assigned His-F8 N delta H proton resonance, revealed that the strain on the Fe-N epsilon bond is in the order horse Mb approximately whale Mb < shark Mb and that the hydrogen bond strength of the His-F8 N delta H proton to the main-chain carbonyl oxygen in the preceding turn of the F helix is in the order shark Mb < horse Mb < whale Mb. Weaker Feporphyrin interaction in shark Mb was manifested in a smaller shift of the heme methyl proton resonance and appears to result from distortion of the coordination geometry in this Mb. Larger strain on the Fe-N epsilon bond in shark Mb should be to some extent attributed to its lowered O2 affinity (P50 = 1.1 mmHg at 20 degrees C), compared to whale and horse Mbs.     

1H nuclear-magnetic-resonance studies of the porcine-pancreatic secretory trypsin inhibitor at 270 MHz

The pancreatic secretory trypsin inhibitor from porcine pancreas has been investigated by high-resolution 1H nuclear magnetic resonance (NMR) at 270 MHz. The presence of a number of slowly exchanging labile protons indicates that the protein is highly globular. Of the two tyrosyl rings, one is free-rotating and solvent-exposed while the other one is hindered in its mobility and buried in the interior of the protein. A lineshape analysis of the temperature dependence of aromatic resonances gave the dynamic parameters for activation of ring mobility. The inhibitor exhibits at least three well-resolved high-field ring-current-shifted methyl resonances. Form II of the inhibitor, that lacks the first four residues, has been compared with the intact form I. No detectable differences were found between the spectra of I and II, which indicates that the presence of the N-terminal tetrapeptide does not appreciably affect the overall conformation of the protein.     

Nuclear-magnetic-resonance-spectroscopic studies of the amino groups of insulin.

The amino groups of insulin have been studied by 1H and 13C nuclear magnetic resonance spectroscopy in insulin, zinc-free insulin and methylated insulin. By difference spectroscopy it is possible to follow the shift with pH of the epsilon-CH2 and delta-CH2 proton resonances of lysine-B29 in insulin. In methylated insulin the dimethyl proton resonances of glycine-A1, phenylalanine-B1 and lysine-B29 can be followed as a function of pH. In native insulin pKapp values of 6.7 and 8.0 are obtained for phenylalanine-B1 and glycine-A1 (the assignment is tentative) and 11.2 for lysine-B29. Separate resonances have been observed from the lysine-B29 Nepsilon-(CH3)2 group for the monomeric and dimeric forms of methylated insulin, which indicates a small change in the environment of lysine-B29 on dimerisation. The nuclear magnetic resonance spectral characteristics of these groups are, in general, consistent with the overall structure of the crystal form of the 2-zinc insulin hexamer.     

Assignment of resonances in the 1H nuclear magnetic resonance spectrum of the carbon monoxide complex of human hemoglobin alpha-chains

Assignments are reported for a substantial number of heme and amino acid proton resonances in the 1H nuclear magnetic resonance spectrum of the carbon monoxide complex of isolated hemoglobin alpha-chains. These resonances provide information on the solution conformation of the protein, particularly in the vicinity of the heme. The heme pocket structure is generally similar to that of carbonmonoxymyoglobin; several conserved residues adopt virtually identical positions relative to the heme in the two proteins. The largest conformational differences involve residues surrounding the ligand-binding site, notably Val62 (E11) and His58 (E7). The chemical shifts of the proximal His87 (F8) resonances are very similar in spectra of the two proteins, indicating a highly conserved coordination geometry and similar hydrogen bonding to the backbone carbonyl of Leu83 (F4).